EP2489670A1 - Method for producing amino acid chelate compounds, amino acid-chelate compounds and use of amino acid-chelate compounds - Google Patents

Abstract

Preparing amino acid chelate compounds, comprises mechanically activating metal oxides, metal carbonates, metal sulfates, metal chlorides and/or metal hydroxides present in solid form, and reacting the activated metal oxides, metal carbonates, metal hydroxides, metal sulfates and/or metal chlorides with amino acids present in solid form, in a solid state reaction to obtain amino acid chelate compounds. An independent claim is also included for the amino acid chelate compounds comprising particles exhibiting finely dispersed and needle-like structure, prepared by the above method. ACTIVITY : Anabolic. No biological data given. MECHANISM OF ACTION : None given.

Description

The invention relates to a process for the preparation of amino acid chelate compounds. Further, it relates to amino acid chelate compounds. Finally, it refers to the use of amino acid chelate compounds.

When metal compounds are reacted with amino acids, so-called chelates are formed. Chelate compounds are u.a. for the metals copper, zinc, manganese, iron, calcium, magnesium, cobalt, vanadium, selenium and nickel and for the amino acids glycine, lysine and methionine.

• Glycin-Eisenchelat-Hydrat (E1), kurz: Eisen-Glycinat
• Glycin-Kupferchelat-Hydrat (E4), kurz: Kupfer-Glycinat
• Glycin-Manganchelat-Hydrat (E5), kurz: Mangan-Glycinat
• Glycin-Zinkchelat-Hydrat (E6), kurz: Zink-Glycinat.

Amino acid chelate compounds are used, inter alia, in animal feed and fertilizer for the supply of trace elements. In animal nutrition, glycine chelates have been increasingly used for several years. In many animal experiments an increase in performance and an improved intestinal absorption compared to trace elements from inorganic compounds were observed. The efficiency of trace elements in the feed can be improved and the excretion rate reduced. The risk of physiological deficiency and performance depression is reduced. In addition, indications were published about possible benefits of organically bound trace elements, eg improved zootechnical and reproductive performance, higher external and internal egg quality, higher incorporation into body organs or tissue. The following glycine chelates are currently available in the feed sector and are available on the market (in brackets the E numbers are given in accordance with the EU Additives Regulation):

• Glycine iron chelate hydrate (E1), in short: iron glycinate
• Glycine-copper chelate hydrate (E4), in short: copper glycinate
• Glycine manganese chelate hydrate (E5), in short: manganese glycinate
• Glycine zinc chelate hydrate (E6), in short: zinc glycinate.

The glycinates currently available on the market differ markedly in particular as regards trace element content, glycine content, solubility in water, color and structure, pH and the amount and type of inorganic anions (sulfates and chlorides). All previously known on the market, so-called Kupferglycinate are either mixed with anions and / or diluted with fillers and / or contain too low glycine content for a true two-fold complexation. The enormous differences can be attributed to the particular manufacturing process used, the raw materials used and the selected reaction ratios between trace element and glycine.

The production of glycine chelates is extremely expensive. It generally starts from solutions of the corresponding trace element compounds with glycine, which are reacted at elevated temperatures. This is followed by evaporation, crystallization, drying and grinding.

The state of the art is for example in the US 4,315,927A . US 4,814,177A . US 830,716A . US 4,599,152A such as US 5,516,925A described.

The patent application CN 2009 / 10030766.3 describes the production of zinc glycinate. Thereafter, in the first step, 5 to 15% glycine are stirred with 5-10% nano-ZnO with water at 50 ° -80 ° C. for 3 to 24 hours and then kept at rest for 6 to 10 hours. The second step is centrifuged at 3,000 to 8,000 min ^-1 and the centrifugate is dried at 80 ° -120 ° C in the oven. The third step involves crushing and classifying larger than 80-120 mesh. In the application CN 2009 / 10030767.8 The same production process for calcium glycinate without centrifugation is described.

The EP 1 529 775 B1 relates to a process for the production of chelates of metals with organic acids, which operates essentially in the anhydrous medium. Are used metal oxides, hydroxides or salts. The organic acid ligant such as glycine, lysine, glutamic acid, etc. and the respective metal compounds such as hydroxides such as copper hydroxide, zinc hydroxide, iron hydroxide, manganese hydroxide, etc. are immersed in non-aqueous liquids such as methanol, ethanol, 1-propanol, hexane, petroleum ether, etc., and at room temperature or elevated temperature mixed together. Since water is also a reaction product, it must be removed using a water separator (eg Dean-Stark water separator). The removal of the respective metal chelate from the organic liquid is carried out by filtration. After drying, the respective metal chelate represents a very fine powder as a finished product.

From the embodiment of EP 1 529 775 B1 shows that the described manufacturing process requires a pretreatment of the metal compounds used. Thus, for example, the preparation of copper hydroxide is based on CuSO ₄ · 5H ₂ O, which is stabilized with KOH at pH 10-11 to precipitate Cu (OH) ₂ . This is followed by a two-fold centrifugation, the be accompanied by washing in ethanol. To produce copper glycinate, Cu (OH) ₂ is then mixed with glycine and this mixture is boiled for five hours in ethanol. The copper glycinate produced under these conditions is filtered off and dried to powder.

The patent applications CN 92107282.1 and CN 2007 / 130121.0 describe the reaction of mixtures of copper acetate and glycine in a one-step solid-state reaction in a ball mill. For this purpose, a mixture of copper acetate and glycine is mixed with water and sodium carbonate and subjected to wet grinding in a ball mill. After grinding for several hours, the suspension is dried, washed with ethanol, centrifuged and dried again.

The DE 10 2004 039 486 A1 describes a dry process for producing organic trace element compounds. Any dry mixture of a | _[RDI] Metal oxide and a solid organic acid are subjected to a mechanical impact by impact and pressure of a Feinstzerkleinerungsmaschine such that the amount of enthalpy released triggers a solid state reaction to a metal salt-like compound.

The focus of this publication is the production of zinc bismethionate from mixtures of ZnO and methionine, which are ground in a mixture with each other. This is proved by a total of seven examples. The remaining three examples have mixtures of CuO and aspartic acid (one of a total of 21 amino acids), mixtures of MnO and malic acid (carboxylic acid ester) and mixtures of Cr (OH) ₃ and nicotinic acid (alkaloids salt-like bound to plant acid).

The review of the process has shown that malfunctions can occur due to caking of regrind on the walls of the mill. These caking can cause the complete cementing of the grinding chamber, which can only be remedied by means of pneumatic hammers and excludes an industrial application. In addition, the product qualities are not reproducible.

Based on this, the object of the invention is to provide a simple, stable and industrially suitable process for the preparation of amino acid chelate compounds. Further, the invention aims to provide amino acid chelate compounds which have advantageous manufacturing properties. Finally, advantageous uses for the amino acid chelate compounds are to be given.

The object is achieved by a method having the features of claim 1. Advantageous embodiments of the method are specified in subclaims.

In the process according to the invention for preparing amino acid chelate compounds, metal oxides and / or metal carbonates and / or metal sulfates and / or metal chlorides and / or metal hydroxides are mechanically activated in solid form and then the activated metal oxides and / or metal carbonates and / or metal sulfates and / or or metal chlorides and / or metal hydroxides with amino acids in solid form and reacted in a solid state reaction to amino acid chelate compounds.

It has been found that the mechanical activation of mixtures of metal compounds and amino acids is not a suitable route. The conversion of metal compounds with the organic acid is rather a spontaneous one chain-like consequence reaction. From an energetic point of view results in the mechanical activation of mixtures whose larger mass fraction requires no mechanical activation, therefore, a large energy loss. This is in the order of the mixing ratio. At a mixing ratio of 1: 2 (CuO to glycine), the non-mechanically activatable fraction is more than 50%. The key reactant in organic acid conversion is the metal compound. According to the invention, this is first activated mechanically. The decoupling of the mechanical activation of the metal compound and the solid-state reaction with an amino acid leads to a decisive influence on the reaction mechanism in the synthesis of metal chelates. After separate mechanical activation of the metal compound, the chelate-solid-state reaction is triggered by adding amino acids. The total conversion of the reaction is considerably improved by the separate mechanical activation of the metal compound. In the solid state reaction, the metal compound and the amino acid are in solid form. In this case, the reactants are dry or substantially dry, ie have at most low moisture contents. Their moisture content is preferably at most 5 wt .-%.

According to a preferred embodiment, the mechanical activation of the metal compounds are supplied as a mixture of loose particles. According to a further embodiment, the amino acids are supplied to the mechanically activated metal compounds in the form of a further mixture of loose particles. The mechanical activation or the solid-state reaction are promoted by the use of the metal compounds in the form of a mixture of loose particles or of the amino acids in the form of a mixture of loose particles. In principle, however, it is also possible for the reactants to be used in the process Feed large coherent pieces, which can be crushed in the implementation of the process.

According to one embodiment of the method, at least one reactant is thermally activated. The thermal activation accelerates the solid-state reaction. During thermal activation, at least one reactant is heated. If the reaction temperature exceeds the boiling point of the water (100 ° C. when the reaction is carried out under normal pressure), the free water of reaction evaporates and is separated from the reactants.

According to a preferred embodiment, the thermal activation takes place simultaneously with the mechanical activation and / or with the reaction in the solid-state reaction. Here, the thermal energy required for the thermal activation of the solid state reaction is selectively supplied. Furthermore, the heat energy released in the mechanical activation or in the implementation of the solid-state reaction can be utilized for the thermal activation. This is the case in particular when carrying out the mechanical activation and / or the solid-state reaction in a mill or another mixing reactor.

According to a further embodiment, water formed during the reaction is separated from the reactants. As a result, caking of reactants on solid surfaces and the associated impairment of the reaction is avoided. The malfunctions and repair work associated with caking in the reactor are likewise avoided. This is especially true when performing the solid state reaction in a mill or other mixing reactor.

In particular, the water can be separated by evaporation from the amino acid chelates. In this case, heat can be supplied and / or the pressure under which the solid-state reaction is carried out can be reduced. Through heat supply, the thermal activation can take place at the same time. Further, the solid state reaction can be carried out in the presence of absorbing solids.

According to a further embodiment, the starting materials are fed dry to the process. This further avoids the risk of caking on solid surfaces. For the starting materials preferably have a maximum water content of 5%. Further preferably, the water content is at most 2.5%.

According to a further embodiment, the activation and the reaction are carried out in the same reactor. In a batch reactor, the metal compounds can first be entered and activated and then added the amino acids and carried out the solid-state reaction. In a continuous flow reactor, the metal compounds can be supplied at a first feed position and, after passing through an activation path at a second feed position, the amino acids are fed in to pass through a reaction zone together with the activated metal compounds.

According to another embodiment, the activation and the reaction are carried out in different reactors. The various reactors may be batch reactors in which the mechanical activation and the reaction are carried out separately and batchwise. Further, the various reactors may be continuous reactors in which the mechanical activation and the reaction are carried out separately from each other in the run.

According to a further embodiment, the activation and / or the reaction are carried out in a vibrating mill and / or in a stirred ball mill and / or in a drum mill and / or in another mixing reactor.

For activation, and optionally the solid state reaction, the metal compounds, and optionally the amino acid, are preferably exposed to mechanical stress by impact and pressure in a comminuting machine. This is preferably an eccentric vibration mill.

In an eccentric vibration mill, the treated material is subjected to mechanical stress, primarily by impact and pressure. An eccentric vibratory mill currently enables the most effective mechanical activation of metal compounds and is also very well suited for carrying out the solid-state reaction. At the same time, thermal activation can be effected by the heat energy released in the eccentric vibration mill.

An eccentric vibration mill suitable for use in the method according to the invention is in the DE 43 35 797 C2 described. Suitable vibratory mills are sold by the company Siebtechnik, Mülheim an der Ruhr, Germany.

The activation and the reaction can be carried out in the same mixing reactor, in different mixing reactors of the same type or in different mixing reactors of different types. In particular, the activation can be carried out in an eccentric vibration mill and the reaction in another type of mixing reactor.

According to one embodiment, the heat generated by the operation of the mixing reactor for thermal activation and / or evaporation of the water is used. In particular, the heat generated by operation of an eccentric vibratory mill alone can cause the thermal activation and / or evaporation of the water. For heating the mixing reactor, if necessary, it is first heated in a warm-up phase. The warm-up phase may coincide with the mechanical activation.

According to one embodiment, the heat for the thermal activation and / or for the evaporation of water is fed to the reactor. The thermal activation and / or the heat required for evaporation can be supplied to the reactor exclusively from the outside. If necessary. In addition to the heat generated by the reactor, further heat can be supplied from the outside.

According to a further embodiment, the thermal activation and / or evaporation is carried out at a temperature between 30 ° and 150 ° C. Furthermore, the thermal activation and / or the evaporation is carried out at a temperature of 80 ° to 120 ° C.

According to a further embodiment, water formed in the reaction is removed from the reactor. The water can be removed during the reaction once, intermittently or continuously.

According to a further embodiment, the reaction is continued during storage of the reaction product outside the reactor. The storage of the reaction product before use can be used to continue the reaction. This increases the availability of the reactor for activation.

According to a preferred embodiment, the reaction product for a continuation of the reaction during storage when removed from the reactor contains free water of reaction. When stored at temperatures below the boiling point, in particular at room temperature, the free water of reaction by ion transport favors a continuation of the reaction. Thus, the reaction can be continued during storage. During the reaction in the reactor, the separation of the water from the reactants can be controlled so that caking on solid surfaces is avoided and a sufficient proportion of free water of reaction remains for reaction during subsequent storage in the reaction product.

According to a further embodiment, the content of the free water in the product is between 1% and 5%. The water content of the product is preferably at most 3%. Further preferably, it is about 2.5%. These water contents prevent the product from clumping and further processing is impaired. The separation of the water in the reaction or during a subsequent storage can be controlled so that the water content of the product is reduced accordingly.

According to a further embodiment, the reaction takes place up to complete stoichiometry. Double-complexed copper glycinate consists of 29.7% by weight of copper and 70.3% by weight of glycine. The mass ratio of copper to glycine is thus 1: 2.37. Mechanical activation of CuO achieves increased water solubility regardless of the glycinate reaction. As a result, the soluble copper content of copper glycinate can be more than stoichiometric and reach more than 35%.

According to a further embodiment, the amino acids of the reaction are fed to the superstoichiometric. As a result, a conversion is promoted to complete stoichiometry.

According to a further embodiment, the mass ratio of the metal oxides and / or the metal carbonates and / or the metal sulfates and / or metal chlorides and / or metal hydroxides to the amino acids is 1: 2 to 1: 5.

According to one embodiment, amino acid chelate compounds of copper and / or zinc and / or manganese and / or iron and / or magnesium and / or calcium and / or nickel and / or cobalt are prepared. According to a further embodiment, amino acid chelate compounds of glycine and / or lysine and / or methionine and / or other amino acids and / or amino acid mixtures are produced.

For complex applications, eg. B. as a digestion additive and as a fertilizer additive, the process of the invention allows the production of Metallkombi chelate compounds, in the mixture of metal compounds z. As the copper, zinc, iron and manganese are mechanically activated and z. B. be reacted with glycine by thermal activation.

Furthermore, the object is achieved by amino acid chelate compounds having the features of one of claims 28 to 31.

According to claim 28, the amino acid chelate compounds have particles with a characteristic acicular crystal structure. This structure is visible under the scanning electron microscope, Fig. 1 shows an example of a recording with the scanning electron microscope (SEM).

According to claim 29, the amino acid chelate compounds contain no sulfates and / or chlorides and have a pH in the range of 4-9. For use as a feed additive, food additive, dietary supplement and electroplating additive has the advantage that no unwanted anions are registered.

According to claim 30, the amino acid chelates have an average particle size of 40 to 60 microns, preferably about 50 microns, and are up to 80% of the particles in the range of 0 - 100 microns and are up to 2% greater than 500 microns. This granulation is particularly advantageous for use as a feed additive, food additive and dietary supplement because of its good spreadability and mixing quality even at low concentrations.

According to claim 31, the amino acid chelate compounds can be prepared by the method of the type described above.

The amino acid chelate compounds according to claims 28 to 31 have the advantage that they can be prepared by a relatively simple, stable and industrially acceptable process.

Finally, the object is solved by claim 32.

According to claim 32, the amino acid chelate compounds of the invention are used as feed additive and / or as a fermentation additive and / or as a fertilizer additive and / or as a food additive and / or as a dietary supplement and / or as a galvanic additive.

The functionality of the method according to the invention is shown for example on the system CuO-glycine under stoichiometric conditions.

The dry synthesis can be described with the following mechanism:

Step 1

Separate mechanical activation of CuO

2nd step

Addition of glycine.

Thermal activation and temperature-controlled conversion with mechanically activated CuO.

Thereafter, in the first step, the separate mechanical activation of CuO is carried out in an eccentric vibration mill with e.g. an energy consumption of about 300 kWh / t, with a time requirement of only about 30 to 60 min. The mill filling is 30%. Since approximately 90% of the applied energy is converted into heat during grinding processes, temperatures between 30 and 150 ° C are obtained with a non-thermostated mill.

After completion of the mechanical activation of CuO, the mill filling is increased in the second step by addition of glycine to 100%. With an energy consumption of only approx. 5 kWh / t, CuO and glycine are reacted in a few minutes. The speed of the reaction depends on the operating temperature of the mill, which causes the thermal activation. The degree of thermal activation is determined by the level of operating temperature. This procedure applies to batch operation in a mill.

However, it is also possible to separate the mechanical and the thermal activation by a series connection. In this case, the decoupled thermal activation would be in a second thermostatic vibratory mill or a thermostated conventional drum mill or a thermostated stirred ball mill or in a thermostated mixer can be stirred.

At temperatures greater than 100 ° C, the conversion is e.g. between 95 and 100%. Below 100 ° C, the remaining water of reaction allows the reaction to continue through storage to complete stoichiometric conversion.

As a control of the degree of conversion, dissolution tests with water are very reliable, whereby the blue color of the tetramine complex becomes visible. X-ray fine-structure recordings also show that the compound formed in accordance with the current ASTM file is Copperbis (glycinato) corresponding to glycine-copper chelate. Fig. 2 shows an example of an X-ray diffraction diagram. The X-ray diffraction is based on the irradiation of powder samples with monochromatic X-ray light. The reflected radiation intensity is measured as a function of the diffraction angle. This results in intensity maxima at defined Angles (2Θ) where certain crystal surfaces, in this case crystal surfaces of the copper glycinate, reflect the X-rays. By comparison with the purest reference samples of copper glycinate with defined diffraction patterns, a clear assignment of crystalline substances is possible.

The subject invention was extended to the dry synthesis of zinc chelate, manganese chelate, iron chelate, nickel chelate and magnesium chelate, calcium chelate and cobalt chelate, and the reaction mechanism confirmed in the same way.

The method according to the invention will be demonstrated below with reference to examples.

Example 1:

The experiments for the process according to the invention were carried out in a 2.7 l volume satellite milling vessel, which was flanged to a 656-0.5 ks eccentric vibration mill. The grinding room of the satellite was lined with ceramics to avoid contamination.

The following operating conditions were used: Rotation speed: 960 min ^-1 Amplitude: 12 mm grinding media: stole

150 g of a copper oxide powder having a particle size of <100 μm were subjected to mechanical activation for 15 minutes in the abovementioned satellite. At the beginning of the activation, the mill had 30 ° C. Thereafter, the mill was stopped and additionally 350 g of glycine supplied to the activated copper oxide. The operating temperature of the mill was then 130 ° C. After 10 minutes of thermal activation of the batch, the process was stopped and steam was released via a drain valve. Even the slightly bluish color of the product indicated that a solid-state reaction had to have expired and that it was a new substance. The product was analyzed for water solubility, crystal lattice structure, grain shape and grain size. The water solubility at room temperature after 10 min. 58%, and after 60 min. 98% of the dissolved Cu in the presence of NH ₃ ions in the known blue tetramine complex [Cu (NH ₃ ) ₄ ] ^-2 converted. The examination of the crystal structure with the X-ray diffractometer X'Pert from Philips showed the main peak of Copperbisglycinato (C ₄ H ₈ CuN ₂ O ₄ ) at the X-ray diffraction angle 2Θ 10.3, in the ESTM file under the number 00-018-1714 is identified.

The result of the measurement of the X-ray diffractometer is in Fig. 2 shown.

The grain shape was examined by the scanning electron microscope and revealed the typical acicular crystals of glycinates and their agglomerates. she is in Fig. 1 shown. In terms of bulk properties, the grain distribution analysis found a ₅₀ d ₅₀ value. The material is free-flowing, has a water content <2% and is stable.

Example 2:

The applicability of the process according to the invention for the production of copper, zinc, iron, manganese and nickel glycinates is demonstrated by means of a mixture of CuO, ZnO, FeSO ₄ .H ₂ O, MnCO ₃ and NiO. For this purpose, in the same test facility as in Example 1, 150 g of the above batch in which each component made up 20%, 25 min. mechanically activated. The satellite was then opened and 300 grams of glycine added. At an operating temperature of 105 ° C, the thermal activation was 5 min. long connected. The resulting water vapor was released via a drain valve.

The dissolution test with water at 25 ° C showed after 60 min. a complete availability of all metals used. The aqueous solution was clear and showed a low olive mixed color. X-ray crystallography was omitted since the glycinate lines of the metals used overlap.

Example 3

As a further example of the applicability of the process of the invention, the preparation of alkaline earth glycinates, magnesium and calcium glycinate is described.

The same experimental device as in Example 1 was used. The procedure for both syntheses was identical, so they are summarized here. 54 g CaO or MgO were each subjected to a 10-minute mechanical activation. In order to have a sufficiently high operating temperature for the thermal activation, the mill had already been brought to an operating temperature of 110 ° C. before idling. After mechanical activation in both cases, a thermal Activation of 15 min. The solubility test was the water solubility at 45 ° C over a period of 10 min. tested.

Upon entry of the produced calcium glycinate in water, a spontaneous complete solubility resulted and it turned in the crystal clear solution has a pH of 7.5.

The magnesium glycinate produced when introduced into water to a pH of 8, resulting in a slightly turbid solution. Adjustment of pH 6 with HCl (gastric acid component) gave a clear solution without the slightest trace of undissolved feed. Under the same dissolution conditions, pure MgO is stable in the presence of HCl to pH 0.

There follow further embodiments of the invention:

1. 1. A process for preparing amino acid chelate compounds, characterized in that metal oxides and / or metal carbonates and / or metal sulfates and / or metal chlorides and / or metal hydroxides are mechanically activated in solid form and then the activated metal oxides and / or metal carbonates and / or metal hydroxides and / or metal sulfates and / or metal chlorides are brought together with amino acids in solid form and reacted in a solid state reaction to amino acid chelate compounds.
2. 2. The method of Example 1, wherein at least one reactant is thermally activated.
3. 3. The method of Example 2, wherein the thermal activation occurs simultaneously with the mechanical activation and / or in which the thermal activation occurs simultaneously with the reaction.
4. 4. The method according to any one of Examples 1 to 3, wherein the water formed in the reaction is separated from the reactants.
5. 5. The method of Example 4, wherein the water is separated by evaporation from the reactants.
6. 6. The method according to any one of Examples 1 to 5, wherein the starting materials are fed dry.
7. 7. The method according to any one of Examples 1 to 6, to which the metal compounds are fed as a mixture of loose particles and / or amino acids as a mixture of loose particles.
8. 8. The method according to any one of Examples 1 to 7, wherein the activation and the reaction are carried out in the same reactor.
9. 9. The method according to any one of Examples 1 to 8, wherein the activation and the reaction are carried out in different reactors.
10. 10. The method according to any one of Examples 1 to 9, wherein the activation and / or the reaction are carried out in a vibrating mill and / or in a stirred ball mill and / or in a drum mill and / or in another mixing reactor.
11. 11. The method according to any one of Examples 1 to 10, wherein the activation and / or the reaction is carried out by mechanical stress by impact and pressure of a comminution machine.
12. 12. The method of Example 10 or 11, wherein the vibrating mill is an eccentric vibrating mill.
13. 13. The method according to any one of Examples 10 to 12, wherein the heat generated by operating the mixing reactor for thermal activation and / or evaporation of the water is used.
14. 14. The method according to any one of Examples 2 to 13, wherein the heat is supplied to the reactor for the thermal activation and / or for the evaporation of water.
15. 15. The method according to any one of Examples 2 to 13, wherein the thermal activation and / or evaporation is carried out at a temperature between 30 and 150 ° C.
16. 16. The method of Example 15, wherein the thermal activation and / or evaporation is carried out at a temperature of 80 to 120 ° C.
17. 17. The method according to any one of Examples 1 to 16, wherein the water formed in the reaction is removed from the reactor.
18. 18. The method according to any one of Examples 1 to 17, wherein the reaction is continued during storage of the reaction product outside the reactor.
19. 19. The method of Example 18, wherein the reaction product when removed from the reactor contains free water of reaction.
20. 20. The method according to any one of Examples 1 to 19, wherein the content of the free water in the product is between 1% and 3%.
21. 21. The method according to any one of Examples 1 to 19, wherein the reaction is carried out to complete stoichiometry.
22. 22. The method according to any one of Examples 1 to 21, wherein the amino acids are supplied to the reaction of stoichiometric.
23. 23. The method according to any one of Examples 1 to 22, wherein the mass ratio of the metal oxides and / or the metal carbonates and / or metal hydroxides and / or the metal sulfates and / or the metal chlorides to the amino acids 1: 2 to 1: 5.
24. 24. The method according to any one of Examples 1 to 23, which is carried out batchwise.
25. 25. The method according to any one of Examples 1 to 24, which is carried out continuously.
26. 26. Method according to one of Examples 1 to 25, wherein the amino acid chelates of copper and / or zinc and / or manganese and / or iron and / or magnesium and / or calcium and / or nickel and / or or cobalt.
27. 27. The method according to any one of Examples 1 to 26, are prepared in the amino acid chelates of glycine and / or lysine and / or methionine and / or other amino acids and / or amino acid mixtures.
28. 28. Amino acid chelate compounds, characterized in that the particles have a finely dispersed, needle-shaped structure.
29. 29 amino acid chelate compounds according to Example 28, characterized in that they contain no sulfates and / or chlorides and have a pH in the range of 4 to 9.
30. 30 amino acid chelate compounds according to Example 28 or 29, characterized in that the average particle size is 40 to 60 microns, up to 80% particles have a particle size of 0 - 100 microns and at most 2%, a particle size of more than 500 microns exhibit.
31. 31. Amino acid chelate compounds, characterized in that they can be prepared by the process according to one of Examples 1 to 27.
32. 32. Use of amino acid chelate compounds according to any of Examples 28 to 31 as a feed additive and / or as a fermentation additive and / or as a fertilizer additive and / or as a food additive and / or as a dietary supplement and / or as a galvanic additive.

Claims (15)

Process for the preparation of amino acid chelate compounds, characterized in that metal oxides and / or metal carbonates and / or metal sulfates and / or metal chlorides and / or metal hydroxides are mechanically activated in solid form and then the activated metal oxides and / or metal carbonates and / or metal hydroxides and / or metal sulfates and / or metal chlorides are brought together with amino acids in solid form and reacted in a solid state reaction to amino acid chelate compounds. The method of claim 1, wherein at least one reactant is thermally activated. Process according to claim 1 or 2, wherein water formed in the reaction is separated by evaporation from the reactants. Method according to one of claims 1 to 3, wherein the starting materials are fed dry. Method according to one of claims 1 to 4, to which the metal compounds are supplied as a mixture of loose particles and / or amino acids as a mixture of loose particles. Method according to one of claims 1 to 5, wherein the activation and / or the reaction in an eccentric vibrating mill and / or in another vibrating mill and / or in a stirred ball mill and / or in a drum mill and / or in another mixing reactor are carried out and / or in which the activation and / or the reaction is carried out by mechanical stress by impact and pressure of a comminution machine. A method according to claim 6, wherein the heat generated by operating the mixing reactor for thermal activation and / or evaporation of the water is used. Method according to one of claims 2 to 7, wherein the thermal activation and / or the evaporation is carried out at a temperature between 30 and 150 ° C, preferably at a temperature of 80 to 120 ° C is performed. Method according to one of claims 1 to 8, wherein the reaction is continued during storage of the reaction product outside a reactor and / or in which the reaction product when removed from the reactor contains free water of reaction. Method according to one of claims 1 to 9, wherein the amino acid chelates of copper and / or zinc and / or manganese and / or iron and / or magnesium and / or calcium and / or nickel and / or the Cobalt be prepared and / or in the amino acid chelates of glycine and / or lysine and / or methionine and / or other amino acids and / or amino acid mixtures. Amino acid chelate compounds, characterized in that the particles have a finely dispersed, needle-shaped structure. Amino acid chelate compounds according to claim 11, characterized in that they contain no sulfates and / or no chlorides and have a pH in the range of 4 to 9. Amino acid chelate compounds according to claim 11 or 12, characterized in that the average particle size is 40 to 60 microns, up to 80% particles have a particle size of 0 - 100 microns and at most 2% have a particle size of more than 500 microns. Amino acid chelate compounds, characterized in that they can be prepared by the process according to one of claims 1 to 10. Use of amino acid chelate compounds according to any one of claims 11 to 14 as a feed additive and / or as a fermentation additive and / or as a fertilizer additive and / or as a food additive and / or as a dietary supplement and / or as a galvanic additive.

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